/* * Copyright (c) 2012-2014 ARM Ltd * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The name of the company may not be used to endorse or promote * products derived from this software without specific prior written * permission. * * THIS SOFTWARE IS PROVIDED BY ARM LTD ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL ARM LTD BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* Implementation of strcmp for ARMv7 when DSP instructions are available. Use ldrd to support wider loads, provided the data is sufficiently aligned. Use saturating arithmetic to optimize the compares. */ /* Build Options: STRCMP_NO_PRECHECK: Don't run a quick pre-check of the first byte in the string. If comparing completely random strings the pre-check will save time, since there is a very high probability of a mismatch in the first character: we save significant overhead if this is the common case. However, if strings are likely to be identical (eg because we're verifying a hit in a hash table), then this check is largely redundant. */ /* This version uses Thumb-2 code. */ .thumb .syntax unified /* Parameters and result. */ #define src1 r0 #define src2 r1 #define result r0 /* Overlaps src1. */ /* Internal variables. */ #define tmp1 r4 #define tmp2 r5 #define const_m1 r12 /* Additional internal variables for 64-bit aligned data. */ #define data1a r2 #define data1b r3 #define data2a r6 #define data2b r7 #define syndrome_a tmp1 #define syndrome_b tmp2 /* Additional internal variables for 32-bit aligned data. */ #define data1 r2 #define data2 r3 #define syndrome tmp2 /* Macro to compute and return the result value for word-aligned cases. */ .macro strcmp_epilogue_aligned synd d1 d2 restore_r6 #ifdef __ARM_BIG_ENDIAN /* If data1 contains a zero byte, then syndrome will contain a 1 in bit 7 of that byte. Otherwise, the highest set bit in the syndrome will highlight the first different bit. It is therefore sufficient to extract the eight bits starting with the syndrome bit. */ clz tmp1, \synd lsl r1, \d2, tmp1 .if \restore_r6 ldrd r6, r7, [sp, #8] .endif .cfi_restore 6 .cfi_restore 7 lsl \d1, \d1, tmp1 .cfi_remember_state lsr result, \d1, #24 ldrd r4, r5, [sp], #16 .cfi_restore 4 .cfi_restore 5 sub result, result, r1, lsr #24 bx lr #else /* To use the big-endian trick we'd have to reverse all three words. that's slower than this approach. */ rev \synd, \synd clz tmp1, \synd bic tmp1, tmp1, #7 lsr r1, \d2, tmp1 .cfi_remember_state .if \restore_r6 ldrd r6, r7, [sp, #8] .endif .cfi_restore 6 .cfi_restore 7 lsr \d1, \d1, tmp1 and result, \d1, #255 and r1, r1, #255 ldrd r4, r5, [sp], #16 .cfi_restore 4 .cfi_restore 5 sub result, result, r1 bx lr #endif .endm .text .p2align 5 .Lstrcmp_start_addr: #ifndef STRCMP_NO_PRECHECK .Lfastpath_exit: sub r0, r2, r3 bx lr nop #endif def_fn strcmp #ifndef STRCMP_NO_PRECHECK ldrb r2, [src1] ldrb r3, [src2] cmp r2, #1 it cs cmpcs r2, r3 bne .Lfastpath_exit #endif .cfi_startproc strd r4, r5, [sp, #-16]! .cfi_def_cfa_offset 16 .cfi_offset 4, -16 .cfi_offset 5, -12 orr tmp1, src1, src2 strd r6, r7, [sp, #8] .cfi_offset 6, -8 .cfi_offset 7, -4 mvn const_m1, #0 lsl r2, tmp1, #29 cbz r2, .Lloop_aligned8 .Lnot_aligned: eor tmp1, src1, src2 tst tmp1, #7 bne .Lmisaligned8 /* Deal with mutual misalignment by aligning downwards and then masking off the unwanted loaded data to prevent a difference. */ and tmp1, src1, #7 bic src1, src1, #7 and tmp2, tmp1, #3 bic src2, src2, #7 lsl tmp2, tmp2, #3 /* Bytes -> bits. */ ldrd data1a, data1b, [src1], #16 tst tmp1, #4 ldrd data2a, data2b, [src2], #16 /* In thumb code we can't use MVN with a register shift, but we do have ORN. */ S2HI tmp1, const_m1, tmp2 orn data1a, data1a, tmp1 orn data2a, data2a, tmp1 beq .Lstart_realigned8 orn data1b, data1b, tmp1 mov data1a, const_m1 orn data2b, data2b, tmp1 mov data2a, const_m1 b .Lstart_realigned8 /* Unwind the inner loop by a factor of 2, giving 16 bytes per pass. */ .p2align 5,,12 /* Don't start in the tail bytes of a cache line. */ .p2align 2 /* Always word aligned. */ .Lloop_aligned8: ldrd data1a, data1b, [src1], #16 ldrd data2a, data2b, [src2], #16 .Lstart_realigned8: uadd8 syndrome_b, data1a, const_m1 /* Only want GE bits, */ eor syndrome_a, data1a, data2a sel syndrome_a, syndrome_a, const_m1 cbnz syndrome_a, .Ldiff_in_a uadd8 syndrome_b, data1b, const_m1 /* Only want GE bits. */ eor syndrome_b, data1b, data2b sel syndrome_b, syndrome_b, const_m1 cbnz syndrome_b, .Ldiff_in_b ldrd data1a, data1b, [src1, #-8] ldrd data2a, data2b, [src2, #-8] uadd8 syndrome_b, data1a, const_m1 /* Only want GE bits, */ eor syndrome_a, data1a, data2a sel syndrome_a, syndrome_a, const_m1 uadd8 syndrome_b, data1b, const_m1 /* Only want GE bits. */ eor syndrome_b, data1b, data2b sel syndrome_b, syndrome_b, const_m1 /* Can't use CBZ for backwards branch. */ orrs syndrome_b, syndrome_b, syndrome_a /* Only need if s_a == 0 */ beq .Lloop_aligned8 .Ldiff_found: cbnz syndrome_a, .Ldiff_in_a .Ldiff_in_b: strcmp_epilogue_aligned syndrome_b, data1b, data2b 1 .Ldiff_in_a: .cfi_restore_state strcmp_epilogue_aligned syndrome_a, data1a, data2a 1 .cfi_restore_state .Lmisaligned8: tst tmp1, #3 bne .Lmisaligned4 ands tmp1, src1, #3 bne .Lmutual_align4 /* Unrolled by a factor of 2, to reduce the number of post-increment operations. */ .Lloop_aligned4: ldr data1, [src1], #8 ldr data2, [src2], #8 .Lstart_realigned4: uadd8 syndrome, data1, const_m1 /* Only need GE bits. */ eor syndrome, data1, data2 sel syndrome, syndrome, const_m1 cbnz syndrome, .Laligned4_done ldr data1, [src1, #-4] ldr data2, [src2, #-4] uadd8 syndrome, data1, const_m1 eor syndrome, data1, data2 sel syndrome, syndrome, const_m1 cmp syndrome, #0 beq .Lloop_aligned4 .Laligned4_done: strcmp_epilogue_aligned syndrome, data1, data2, 0 .Lmutual_align4: .cfi_restore_state /* Deal with mutual misalignment by aligning downwards and then masking off the unwanted loaded data to prevent a difference. */ lsl tmp1, tmp1, #3 /* Bytes -> bits. */ bic src1, src1, #3 ldr data1, [src1], #8 bic src2, src2, #3 ldr data2, [src2], #8 /* In thumb code we can't use MVN with a register shift, but we do have ORN. */ S2HI tmp1, const_m1, tmp1 orn data1, data1, tmp1 orn data2, data2, tmp1 b .Lstart_realigned4 .Lmisaligned4: ands tmp1, src1, #3 beq .Lsrc1_aligned sub src2, src2, tmp1 bic src1, src1, #3 lsls tmp1, tmp1, #31 ldr data1, [src1], #4 beq .Laligned_m2 bcs .Laligned_m1 #ifdef STRCMP_NO_PRECHECK ldrb data2, [src2, #1] uxtb tmp1, data1, ror #BYTE1_OFFSET subs tmp1, tmp1, data2 bne .Lmisaligned_exit cbz data2, .Lmisaligned_exit .Laligned_m2: ldrb data2, [src2, #2] uxtb tmp1, data1, ror #BYTE2_OFFSET subs tmp1, tmp1, data2 bne .Lmisaligned_exit cbz data2, .Lmisaligned_exit .Laligned_m1: ldrb data2, [src2, #3] uxtb tmp1, data1, ror #BYTE3_OFFSET subs tmp1, tmp1, data2 bne .Lmisaligned_exit add src2, src2, #4 cbnz data2, .Lsrc1_aligned #else /* STRCMP_NO_PRECHECK */ /* If we've done the pre-check, then we don't need to check the first byte again here. */ ldrb data2, [src2, #2] uxtb tmp1, data1, ror #BYTE2_OFFSET subs tmp1, tmp1, data2 bne .Lmisaligned_exit cbz data2, .Lmisaligned_exit .Laligned_m2: ldrb data2, [src2, #3] uxtb tmp1, data1, ror #BYTE3_OFFSET subs tmp1, tmp1, data2 bne .Lmisaligned_exit cbnz data2, .Laligned_m1 #endif .Lmisaligned_exit: .cfi_remember_state mov result, tmp1 ldr r4, [sp], #16 .cfi_restore 4 bx lr #ifndef STRCMP_NO_PRECHECK .Laligned_m1: add src2, src2, #4 #endif .Lsrc1_aligned: .cfi_restore_state /* src1 is word aligned, but src2 has no common alignment with it. */ ldr data1, [src1], #4 lsls tmp1, src2, #31 /* C=src2[1], Z=src2[0]. */ bic src2, src2, #3 ldr data2, [src2], #4 bhi .Loverlap1 /* C=1, Z=0 => src2[1:0] = 0b11. */ bcs .Loverlap2 /* C=1, Z=1 => src2[1:0] = 0b10. */ /* (overlap3) C=0, Z=0 => src2[1:0] = 0b01. */ .Loverlap3: bic tmp1, data1, #MSB uadd8 syndrome, data1, const_m1 eors syndrome, tmp1, data2, S2LO #8 sel syndrome, syndrome, const_m1 bne 4f cbnz syndrome, 5f ldr data2, [src2], #4 eor tmp1, tmp1, data1 cmp tmp1, data2, S2HI #24 bne 6f ldr data1, [src1], #4 b .Loverlap3 4: S2LO data2, data2, #8 b .Lstrcmp_tail 5: bics syndrome, syndrome, #MSB bne .Lstrcmp_done_equal /* We can only get here if the MSB of data1 contains 0, so fast-path the exit. */ ldrb result, [src2] .cfi_remember_state ldrd r4, r5, [sp], #16 .cfi_restore 4 .cfi_restore 5 /* R6/7 Not used in this sequence. */ .cfi_restore 6 .cfi_restore 7 neg result, result bx lr 6: .cfi_restore_state S2LO data1, data1, #24 and data2, data2, #LSB b .Lstrcmp_tail .p2align 5,,12 /* Ensure at least 3 instructions in cache line. */ .Loverlap2: and tmp1, data1, const_m1, S2LO #16 uadd8 syndrome, data1, const_m1 eors syndrome, tmp1, data2, S2LO #16 sel syndrome, syndrome, const_m1 bne 4f cbnz syndrome, 5f ldr data2, [src2], #4 eor tmp1, tmp1, data1 cmp tmp1, data2, S2HI #16 bne 6f ldr data1, [src1], #4 b .Loverlap2 4: S2LO data2, data2, #16 b .Lstrcmp_tail 5: ands syndrome, syndrome, const_m1, S2LO #16 bne .Lstrcmp_done_equal ldrh data2, [src2] S2LO data1, data1, #16 #ifdef __ARM_BIG_ENDIAN lsl data2, data2, #16 #endif b .Lstrcmp_tail 6: S2LO data1, data1, #16 and data2, data2, const_m1, S2LO #16 b .Lstrcmp_tail .p2align 5,,12 /* Ensure at least 3 instructions in cache line. */ .Loverlap1: and tmp1, data1, #LSB uadd8 syndrome, data1, const_m1 eors syndrome, tmp1, data2, S2LO #24 sel syndrome, syndrome, const_m1 bne 4f cbnz syndrome, 5f ldr data2, [src2], #4 eor tmp1, tmp1, data1 cmp tmp1, data2, S2HI #8 bne 6f ldr data1, [src1], #4 b .Loverlap1 4: S2LO data2, data2, #24 b .Lstrcmp_tail 5: tst syndrome, #LSB bne .Lstrcmp_done_equal ldr data2, [src2] 6: S2LO data1, data1, #8 bic data2, data2, #MSB b .Lstrcmp_tail .Lstrcmp_done_equal: mov result, #0 .cfi_remember_state ldrd r4, r5, [sp], #16 .cfi_restore 4 .cfi_restore 5 /* R6/7 not used in this sequence. */ .cfi_restore 6 .cfi_restore 7 bx lr .Lstrcmp_tail: .cfi_restore_state #ifndef __ARM_BIG_ENDIAN rev data1, data1 rev data2, data2 /* Now everything looks big-endian... */ #endif uadd8 tmp1, data1, const_m1 eor tmp1, data1, data2 sel syndrome, tmp1, const_m1 clz tmp1, syndrome lsl data1, data1, tmp1 lsl data2, data2, tmp1 lsr result, data1, #24 ldrd r4, r5, [sp], #16 .cfi_restore 4 .cfi_restore 5 /* R6/7 not used in this sequence. */ .cfi_restore 6 .cfi_restore 7 sub result, result, data2, lsr #24 bx lr .cfi_endproc .size strcmp, . - .Lstrcmp_start_addr